control apparatus to control operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, comprises: a detector configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers; an output data item interpolator configured to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer; and output control circuitry configured, in response to a current occupancy difference exceeding a threshold occupancy difference, to change the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, the output control circuitry being configured to progressively vary the read offset displacement so as to define an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer; the output control circuitry being further configured, when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, to inhibit operation of the output data item interpolator and to control output of an output data item from the data buffer location pointed to by the read pointer.
|
16. A control apparatus configured to control operation of a data buffer to which data items are written according to a write pointer that advances in position in response to an input data item rate, and from which data items are read according to a read pointer that advances in position in response to an output data item rate, the control apparatus comprising:
detection circuitry configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, wherein the current buffer occupancy represents a difference between the read and write pointers;
output data item interpolation circuitry configured to interpolate a data item at an interpolated data buffer location, which is defined by a read offset displacement from a data buffer location pointed to by the read pointer, wherein the output control circuitry is further configured to change the read pointer from an initial read pointer to a target read pointer by progressively changing the read offset displacement to have a progressively increasing magnitude; and
output control circuitry configured to output an interpolated data item so as to reduce the occupancy difference, and when the occupancy difference is less than the threshold occupancy difference, inhibit operation of the output data item interpolation circuitry and control output of an output data item from the data buffer location pointed to by the read pointer.
15. A method, comprising:
controlling operation of a data buffer to which data items are written according to a write pointer that advances in position in response to an input data item rate, and from which data items are read according to a read pointer that advances in position in response to an output data item rate;
detecting an occupancy difference between a current buffer occupancy and a target buffer occupancy, wherein the current buffer occupancy represents a difference between the read and write pointers;
interpolating, by output data item interpolation circuitry, a data item at an interpolated data buffer location, which is defined by a read offset displacement from a data buffer location pointed to by the read pointer;
in response to a current occupancy difference exceeding a threshold occupancy difference, changing the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, and, in response to changing the read pointer by the change amount, progressively varying the read offset displacement by progressively applying an offset having an opposite polarity from the change amount so as to define the interpolated data buffer location, which progressively changes over the output of a transitional group of data items towards a location pointed to by the target read pointer; and
when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, inhibiting operation of the output data item interpolation circuitry and controlling output of an output data item from the data buffer location pointed to by the read pointer.
1. A control apparatus configured to control operation of a data buffer to which data items are written according to a write pointer that advances in position in response to an input data item rate, and from which data items are read according to a read pointer that advances in position in response to an output data item rate, the control apparatus comprising:
detection circuitry configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, wherein the current buffer occupancy represents a difference between the read and write pointers;
output data item interpolation circuitry configured to interpolate a data item at an interpolated data buffer location, which is defined by a read offset displacement from a data buffer location pointed to by the read pointer; and
output control circuitry configured to, in response to determining that a current occupancy difference exceeds a threshold occupancy difference, change the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, the output control circuitry being further configured to, in response to changing the read pointer by the change amount, progressively vary the read offset displacement by progressively applying an offset having an opposite polarity from the change amount so as to define the interpolated data buffer location, which progressively changes over output of a transitional group of data items towards a location pointed to by the target read pointer,
wherein the output control circuitry is further configured to, when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, inhibit operation of the output data item interpolation circuitry and control output of an output data item from the data buffer location pointed to by the read pointer.
2. The control apparatus according to
3. The control apparatus according to
4. The control apparatus according to
5. The control apparatus according to
6. The control apparatus according to
7. The control apparatus according to
8. The control apparatus according to
9. The control apparatus according to
10. The control apparatus of
11. A data buffer apparatus, comprising:
a data buffer; and
the control apparatus according to
13. The data buffer apparatus according to
a video buffer; and
a video buffer controller configured to detect occupancy of the video buffer, and, in response to the detection, initiate dropping or repeating of a video frame for output by the video buffer,
wherein the output control circuitry is responsive to the video buffer controller to compensate, over a transitional period, for a net reduction or increase in an output data rate, in response to the dropping or the repeating of a video frame.
14. The data buffer apparatus according to
17. The control apparatus according to
18. The control apparatus of
|
This disclosure relates to data buffers and data buffer control.
In the context of a data buffer such as an audio buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, current buffer occupancy represents a difference between the read and write pointers.
To avoid data overflow or underflow, a target buffer occupancy may be specified, an occupancy difference between a current buffer occupancy and a target buffer occupancy can be detected. In response to the occupancy difference exceeding a threshold, it is possible to drop or repeat output data items from the data buffer. However, such a coarse adjustment can give rise to discontinuities in the output data stream, which can be a particular problem if the data items represent, for example, audio samples.
Another approach is interpolation amongst output data items, but this can also give rise to noise and/or distortion.
The foregoing paragraphs have been provided by way of general introduction, and are not intended to limit the scope of the following claims. The described embodiments, together with further advantages, will be best understood by reference to the following detailed description taken in conjunction with the accompanying drawings.
Various aspects and features of the present disclosure are defined in the appended claims and within the text of the accompanying description and include at least a head mountable apparatus such as a display and a method of operating a head-mountable apparatus as well as a computer program.
A more complete appreciation of the disclosure and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
Referring to the drawings,
Different respective buffers are used for the video and audio data, in part because of differences in properties of these types of data. For example, in order to deal with a video buffer becoming either too full or insufficiently full, for example because of data rate discrepancies between the rate at which data is written to the buffer and the rate at which data is read from the buffer, it is generally necessary to skip a video frame or repeat a video frame, because temporal interpolation between video frames for rate conversion is relatively processor-intensive and can degrade the video quality. In contrast, for the audio buffer 140, a simple approach to dealing with data rate discrepancies between audio data 130 provided to the audio buffer and the audio data read out from the audio buffer is to skip or repeat samples on a sample-by-sample basis.
The present embodiments will discuss the handling of rate discrepancies on a sample-by-sample basis. While an audio buffer is used as an example, the present techniques are applicable to a buffer for any sample-based data for which inter-sample interpolation provides a meaningful outcome—for example, a buffer of samples indicating temperature measurements, a buffer of samples indicating voltage detections or the like.
As mentioned above, issues relating to an insufficiently full buffer or an over-full buffer can arise because of discrepancies between the data rate of data items supplied to the respective buffer and the data rate at which data items are required from the data buffer. In the case of audio data, for example, there may be a nominal data rate of, for example, 48000 samples per second or 44100 samples per second. Indeed, this nominal data rate could be the same as between the A/V source 110 and the A/V sink 150, but normal tolerances in, for example, crystal-controlled oscillators controlling operations at the respective devices can lead to minor discrepancies between the data rate at inputs to the audio buffer 140 and the data rate at output from the audio buffer 140.
A read pointer 260 follows the write pointer in the direction 220 and indicates a location at which data is read from the buffer. As a data item is read, the read pointer advances in position in a direction 270, or in other words the same direction as the direction 220, once again taking a cyclic path 280 back to the start 250 of the memory 200 when it reaches the end 230.
The region 290 between the prevailing read pointer and the prevailing write pointer is a region in which currently unread data is held, and represents the current occupancy of the data buffer.
For a reliably operating system, the current occupancy ideally sits at a target occupancy level, which may be (purely by way of example) equivalent to 50% of the size of the memory 200. If the buffer occupancy drops too low, there is a danger that the buffer will run out of data and will be unable to service read operations as they are required. On the other hand, if the buffer occupancy grows too large, there is a danger that the size of the buffer 200 may be insufficient and the buffer will overfill, causing data to be discarded at the input side.
One way in which the occupancy of a data buffer could be managed is by controlling the rate of writing to and reading from the data buffer. However, since the rate of writing to the data buffer may be outside the control of the buffer arrangement in use (for example, being determined by the data output rate of a potentially remote piece of apparatus such as the A/V source 110), a way in which local control of the buffer occupancy can be achieved is to control the rate at which data is read out from the buffer. The example arrangements discussed below deal with controlling the reading of data from a data buffer.
It will be appreciated that in terms of the comparison of a value such as a current occupancy difference (between a current buffer occupancy and a target buffer occupancy) with a threshold such as a margin, various entirely equivalent formulations can be used. In the present case using an example margin of 64, the following are entirely equivalent at a technical level:
Current occupancy difference > 63
Current occupancy difference >= 64
And similarly the following are entirely equivalent at a technical level
Current occupancy difference < 64
Current occupancy difference <= 63
The skilled person will fully realise that references to comparison with a threshold can refer to either equivalent statement as set out above.
The operation of the apparatus 400 will be discussed in greater detail below, but in brief, the apparatus 400 comprises detection circuitry 420 configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy in which the current buffer occupancy represents (as discussed above) a difference between the read and write pointers. The apparatus 400 also comprises output control circuitry which can control the advance of the read pointer and an interpolator 430. The operation of the output control and interpolation circuitry will be discussed in more detail below.
a detector 420 configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
an output data item interpolator 430 configured to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer; and
output control circuitry 430 configured, in response to a current occupancy difference exceeding a threshold occupancy difference, to change the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, the output control circuitry being configured to progressively vary the read offset displacement so as to define an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer;
the output control circuitry being configured, when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, to inhibit operation of the output data item interpolator and to control output of an output data item from the data buffer location pointed to by the read pointer.
a data buffer 410; and
control apparatus 400 to control operation of the data buffer.
With regard to the notation in
A subtractor 500 detects the difference 502 between the write pointer 504 and the read pointer 506. This difference 502 represents the current occupancy of the data buffer.
A subtractor 508 detects the difference between the current occupancy 502 and a target occupancy 510. Purely as an example, the target occupancy may be 50% of the buffer size. The outcome 512, a signed value, is provided to a divider 514 and to an absolute value detector 560.
The output of the divider 454, a value 516, is zero if the magnitude of the occupancy difference 512 is less than 64. It will be +1 if the occupancy difference 512 is between 64 and 127, and it will be −1 if the occupancy difference 512 is between −64 and −127 and so on.
A sign bit SGN of the value 512 is provided as an input 518 to a read counter 520. The value 516 is also provided as one input to an adder 522. Other inputs include an input 524 to be discussed below and an input representing a current read shift value to be discussed below.
At the output of the adder 522, a signed 11 bit value is generated as a value 528, from which an overflow indicator OVF 530 (to be discussed below) is provided as another input to the read counter 520, and the remaining magnitude 532 provided as an unsigned 10 bit value to a register 534. The register 534 stores the read shift value 526 as an unsigned 10 bit value. Therefore, the read shift value can vary between 0 and 1023.
The read shift value 526 provides an input to an interpolator 536 in which the read shift value is multiplied (by a multiplier 538) by a data item 540 read from the data buffer location corresponding to the read pointer +1, the product 542 being provided to an adder 544. Another input to the adder 544 is the product, generated by a multiplier 546, of a data item 548 read from the data buffer location corresponding to the read pointer, which is multiplied by (1024-read shift value), as generated by a subtractor.
Note that the multiplications by the multipliers 546, 538 are normalised with respect to the range of 1024 applicable to the 10 bit read shift value. So, the multiplication at 538 is a multiplication by the read shift value/1024, and the multiplication at 546 (shown in
This provides an example in which the output control circuitry is configured to progressively vary the read offset displacement by 1/nth of the separation of adjacent data buffer locations at each output data item generation. For example, n may be an integer power of two, greater than 1 (such as 1024=210). This feature gives rise to a technique by which the output control circuitry defines an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer. For example, the transitional group may comprise 1024 samples.
So, the interpolator is an example of a two-tap interpolator configured to interpolate a data item 552 for output at an interpolated data buffer location display by the read shift value 526 from the data buffer location point to by the read pointer (corresponding to the data item 548). The interpolator can interpolate from a data buffer location pointed to by the read pointer and a data item at an adjacent data buffer location, according to an interpolation ratio defining the interpolated data buffer location between the data buffer location pointed to by the read pointer and the adjacent data buffer location.
So, for example, if the read shift value is zero, then the output data item 552 is equal to the read data item 548 and (in effect at least) an interpolation operation is inhibited and is not applied because there is no contribution from the data item 540. This is the normal quiescent mode of operation of the apparatus, in that a read shift is generated and applied using the techniques to be discussed below only when it is needed, normally temporarily, in response to the buffer becoming too full or too empty, by more than the margin amount.
If the read shift value 526 is (for example) a value of 512 then the output data item 552 is equal to a 50:50 mix of the data items 540, 548, corresponding to an interpolated buffer location halfway between the location pointed to by the read pointer and a next adjacent location.
The read counter 520 advances the read pointer at each read operation according to the truth table shown in
Returning to the occupancy difference value 512, this is also provided to the absolute value detector 560 generating an absolute value 562 or magnitude for the occupancy difference. A detector 564 detects whether this magnitude is less than 64 and provides a signal to an A/VD gate 566 in dependence upon the detection. The signal is a 1 if the absolute value 562 is less than 64, and 0 otherwise.
A comparator 568 compares the read shift amount with 0. If it is greater than 0 than a signal 570 is supplied as a “1” to the A/VD gate 566, and otherwise a 0 is provided. The two inputs to the A/VD gate 566 are combined by a logical A/VD operation to generate a signal 572 which controls the operation of the second 574 of a series of two multiplexers 576, 574.
The multiplexer 576 is controlled by the SGN signal 528 and selects either +1 or −1 in dependence upon the state of SGN. This output is provided to the multiplexer 574 which selects either the output of the multiplexer 574 or 0 as the signal 524.
The effect of the circuitry controlling the generation of the signal 524 is as follows.
If the current occupancy difference has a magnitude less than the margin (such as 64) but the current read shift amount is non-zero, then the input 524 will represent a value +1 or −1 selected (at 576) according to whether the value SGN indicates a positive or negative output from the divider 514. If either the current occupancy difference is greater than the margin, or the current read shift is zero, then the input 524 makes no contribution to the sum generated by the adder 522.
In these diagrams, successive read clock cycles are indicated by successive columns of data. A representation of an excess of write operations over read operations is indicated schematically by two write operations appearing in the same read cycle, but it will be appreciated that such excess write operations do not necessarily align with individual read operations and instead are considered according to their net effect on the balance between write and read operations and the resulting buffer occupancy.
First,
Referring to
In a second column of
At the next read/write operation, denoted by the third column of
This arrangement demonstrates the action of the register 534 as a cyclic counter configured to generate a count value between 0 and n, the count value being indicative of the read offset displacement, and to change the count value at each output data item generation.
At the next instance 705 of an excess write operation, the value 512 moves up to 65. Read shift continues to increment up to 1023 at a stage 715 however, the signal 528 has reached an overflow situation causing an advance of the read pointer by +2 at a stage 720. The advance at the stage 720 still leaves one net excess write operation to be dealt with so the read shift amount continues to progress back up to 1023 at a stage 725 at which time a further read operation is introduced by advancing the read pointer by +2 at a stage 730. The read shift value returns to zero and the value 512 returns to 63.
Note that an alternative to this operation would be to decrement the Read Shift once buffer occupancy drops below threshold until the Read Shift reaches zero, resulting in a final buffer occupancy of 63, which would of course be within the margin. An option is to continue incrementing if the Read Shift is over 511/1023 and to decrement if below that amount in order to get to the zero position quickest, so as to reduce the number of samples for which interpolation is used. This provides an example of an arrangement in which the output control circuitry is configured, in response to detection by the detector that the current occupancy difference no longer exceeds the threshold occupancy difference, to progressively vary the read offset displacement so as to align the interpolated data buffer location with a given data buffer location.
Note that the value 528 is shown here as a 12-bit hexadecimal number using two's complement arithmetic, so −1 decimal is zero x FFF in hexadecimal. In other words, SGN equals 1, OVF equals 1, and the bottom ten bits equal 0x3FF or 1023 decimal.
As the OVF bit has been set and the SGN has been set, the read pointer increments by plus zero or a net decrement of one, so the value 512 returns to −63, the value 516 goes to zero and the value 524 goes to −1. The value 528 goes to 3FE. The value 528 keeps on decrementing so that the read shift value 526 goes from 1023 down towards zero. At the last column 810 of
Accordingly, interpolation can be inhibited in these examples by setting Read Shift=0.
A frame skip or frame repeat operation causes a disruption in the audio signal of one frame's worth of audio data, for example 800 samples in a 48 kHz audio sample rate and 60 video frames per second system. Notice of this advance scheduling of a repeat or skip operation is provided to the audio buffer as the signal 900, and at the audio buffer (a part of which is shown as circuitry 1170, it is used to initiate the dropping or repeating of multiple audio samples and the control of read operations at the audio buffer in a similar manner to that discussed above, in order to adapt the output audio signal to the timing transition caused by the dropping or repeating of a video frame, with the aim of re-aligning the audio signal (at least after a transitional period) with the video signal so as to maintain so-called lip synchronisation.
The rate control at the audio buffer can itself be carried out over a transitional period.
Similarly, in
Therefore,
The examples above concern a target occupancy of 50% of the buffer size and a margin in this example of 64 samples. However, both of these are configurable parameters of the apparatus. Indeed, in some examples the margin could be 1 sample but this could lead to near-continuous interpolation by the apparatus even for very tiny discrepancies in input and output data rates. But more generally, an event detector 1400 (
a detection of an abrupt change in input or output data rate; or
a detection that data at another input (in a multiple input system) is unsynchronised with the data handled by the present buffer.
detecting (at a step 1800) an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
providing (at a step 1810) an output data item interpolator to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from the data buffer location pointed to by the read pointer;
at a step 1820, in response to a current occupancy difference exceeding a threshold occupancy difference (Thr), changing (at a step 1830) the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, by progressively varying the read offset displacement so as to define an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer; and
when (at a step 1840) the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer (implied by no longer being under the control of the step 1830), inhibiting operation of the output data item interpolator and controlling output of an output data item from the data buffer location pointed to by the read pointer.
One option, as shown in
In another example, the read pointer is incremented straight away (as shown by a schematic arrow 1930) and a read shift of −1023/1024 is applied 1935, steadily increasing in magnitude (and negative polarity) towards a zero interpolation (represented schematically by a smaller arrow 1940) at the end of a series 1938 representing this process.
Note that in either
In
However, in other examples, the read pointer is initially decremented (represented by a schematic arrow 1960) to the target position 1910 and then a positive read shift +1023 is applied, reducing down in a progression 1970 to +1, 0 interpolation at which point interpolation is effectively switched off.
Note again that in either
The example of
detecting (at a step 2000) an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
interpolating (at a step 2010) a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer;
outputting (at a step 2020) an interpolated data item so as to reduce the occupancy difference; and
when the occupancy difference is less than the threshold occupancy difference, inhibiting (at a step 2030) the interpolating step and controlling output of an output data item from the data buffer location pointed to by the read pointer.
Further embodiments of the disclosure (for example, as represented by
Control apparatus to control operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, the apparatus comprising:
a detector configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
an output data item interpolator configured to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from the data buffer location pointed to by the read pointer; and
output control circuitry configured to output an interpolated data item so as to reduce the occupancy difference and when the occupancy difference is less than the threshold occupancy difference to inhibit operation of the output data item interpolator and to control output of an output data item from the data buffer location pointed to by the read pointer.
Further embodiments provide that the inhibiting of the output data item interpolator is when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with a target read pointer.
Respective aspects and features of the present disclosure are defined by the following numbered clauses:
1. Control apparatus to control operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, the apparatus comprising:
a detector configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
an output data item interpolator configured to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer; and
output control circuitry configured, in response to a current occupancy difference exceeding a threshold occupancy difference, to change the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, the output control circuitry being configured to progressively vary the read offset displacement so as to define an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer;
the output control circuitry being further configured, when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, to inhibit operation of the output data item interpolator and to control output of an output data item from the data buffer location pointed to by the read pointer.
2. Control apparatus according to clause 1, in which the output control circuitry is configured to change the read pointer from an initial read pointer to a target read pointer by first applying the change amount to the read pointer and then applying an offset having an opposite polarity to the change amount and a progressively reducing magnitude, the read offset displacement representing a sum of the change amount and the applied offset.
3. Control apparatus according to clause 1 or clause 2, in which the output control circuitry is configured to change the read pointer from an initial read pointer to a target read pointer by applying a read offset displacement having the same polarity as the change amount and a progressively increasing magnitude.
4. Control apparatus according to any one of clauses 2 and 3, in which the output control circuitry is configured to progressively vary the read offset displacement by 1/nth of the separation of adjacent data buffer locations at each output data item generation.
5. Control apparatus according to clause 4, in which n is an integer power of two, greater than 1.
6. Control apparatus according to clause 5, in which the output control circuitry comprises a cyclic counter configured to generate a count value between 0 and n, the count value being indicative of the read offset displacement, and to change the count value at each output data item generation.
7. Control apparatus according to any one of the preceding clauses, in which the threshold occupancy difference is more than one data item.
8. Control apparatus according to any one of the preceding clauses, in which the input data item rate is defined by an input clock signal and the output data item rate is defined by an output clock signal.
9. Control apparatus according to any one of the preceding clauses, in which the interpolator is a two-tap interpolator configured to interpolate between a data item at the data buffer location pointed to by the read pointer and a data item at an adjacent data buffer location, according to an interpolation ratio defining the interpolated data buffer location between the data buffer location pointed to by the read pointer and the adjacent data buffer location.
10. Control apparatus according to any one of the preceding clauses, comprising an event detector configured to detect an event of a set of one or more predetermined events, and a controller configured to control one or both of the target buffer occupancy and the threshold occupancy difference in response to a detected event.
11. Control apparatus according to any one of the preceding clauses, in which the output control circuitry is configured, in response to detection by the detector that the current occupancy difference no longer exceeds the threshold occupancy difference, to progressively vary the read offset displacement so as to align the interpolated data buffer location with a given data buffer location.
12. Data buffer apparatus comprising:
a data buffer; and
control apparatus according to any one of the preceding clauses, to control operation of the data buffer.
13. Apparatus according to clause 12, in which the data items are audio samples.
14. Apparatus according to clause 12 or clause 13, comprising:
a video buffer; and
a video buffer controller configured to detect the occupancy of the video buffer and, in response to the detection, to initiate the dropping or repeating of a video frame for output by the video buffer;
in which the output control circuitry is responsive to the video buffer controller to compensate, over a transitional period, for a net reduction or increase in the output data rate in response to the dropping or repeating of a video frame.
15. Apparatus according to clause 14, in which the output control circuitry is configured to start the transitional period before the dropping or repeating of the video frame.
16. A method of controlling operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, the method comprising:
detecting an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
providing an output data item interpolator to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer;
in response to a current occupancy difference exceeding a threshold occupancy difference, changing the read pointer from an initial read pointer to a target read pointer by a change amount so as to reduce the occupancy difference, by progressively varying the read offset displacement so as to define an interpolated data buffer location which progresses over the output of a transitional group of data items towards the location pointed to by the target read pointer; and
when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with the target read pointer, inhibiting operation of the output data item interpolator and controlling output of an output data item from the data buffer location pointed to by the read pointer.
17. Control apparatus to control operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, the apparatus comprising:
a detector configured to detect an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
an output data item interpolator configured to interpolate a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer; and
output control circuitry configured to output an interpolated data item so as to reduce the occupancy difference and when the occupancy difference is less than the threshold occupancy difference to inhibit operation of the output data item interpolator and to control output of an output data item from the data buffer location pointed to by the read pointer.
18. Control apparatus according to clause 17, in the output control circuitry is configured to inhibit the output data item interpolator is when the occupancy difference is less than the threshold occupancy difference and the interpolated data buffer location is aligned with a target read pointer.
19. A method of controlling operation of a data buffer to which data items are written according to a write pointer which advances in position in response to an input data item rate and from which data items are read according to a read pointer which advances in position in response to an output data item rate, the method comprising:
detecting an occupancy difference between a current buffer occupancy and a target buffer occupancy, in which the current buffer occupancy represents a difference between the read and write pointers;
interpolating a data item at an interpolated data buffer location displaced by a read offset displacement from a data buffer location pointed to by the read pointer;
outputting an interpolated data item so as to reduce the occupancy difference; and
when the occupancy difference is less than the threshold occupancy difference, inhibiting the interpolating step and controlling output of an output data item from the data buffer location pointed to by the read pointer.
It will be appreciated that in example embodiments the techniques discussed above, including the method represented by
It will also be apparent that numerous modifications and variations of the present disclosure are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the disclosure may be practised otherwise than as specifically described herein.
It will be appreciated that the above description for clarity has described embodiments with reference to different functional units, circuitry and/or processors. However, it will be apparent that any suitable distribution of functionality between different functional units, circuitry and/or processors may be used without detracting from the embodiments.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
6247072, | Jan 27 1998 | Cisco Systems, Inc; CISCO SYSTEMS, ICN ; Cisco Technology, Inc | Real-time data rate matching across a medium |
7023488, | Apr 20 2001 | EVERTZ MICROSYSTEMS LTD | Circuit and method for live switching of digital video programs containing embedded audio data |
7519747, | Sep 11 2003 | XILINX, Inc. | Variable latency buffer and method of operation |
8311094, | Dec 22 2004 | British Telecommunications public limited company | Buffer underflow prevention |
8650238, | Nov 28 2007 | Qualcomm Incorporated | Resolving buffer underflow/overflow in a digital system |
8917797, | Jun 29 2001 | AVAGO TECHNOLOGIES INTERNATIONAL SALES PTE LIMITED | Method and apparatus for controlling buffer overflow in a communication system |
9324336, | Oct 20 2011 | LG Electronics Inc | Method of managing a jitter buffer, and jitter buffer using same |
20050141033, | |||
20060285557, | |||
20070008984, | |||
20120268653, | |||
20130107930, | |||
20130235152, | |||
20150200771, | |||
20170070363, | |||
CN101084678, |
Executed on | Assignor | Assignee | Conveyance | Frame | Reel | Doc |
Feb 15 2019 | Sony Corporation | (assignment on the face of the patent) | / | |||
Mar 05 2019 | KEATING, STEPHEN MARK | SONY EUROPE LIMITED | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 058359 | /0797 | |
Mar 05 2019 | SONY EUROPE LIMITED | Sony Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 059068 | /0620 |
Date | Maintenance Fee Events |
Aug 20 2020 | BIG: Entity status set to Undiscounted (note the period is included in the code). |
Date | Maintenance Schedule |
Jun 14 2025 | 4 years fee payment window open |
Dec 14 2025 | 6 months grace period start (w surcharge) |
Jun 14 2026 | patent expiry (for year 4) |
Jun 14 2028 | 2 years to revive unintentionally abandoned end. (for year 4) |
Jun 14 2029 | 8 years fee payment window open |
Dec 14 2029 | 6 months grace period start (w surcharge) |
Jun 14 2030 | patent expiry (for year 8) |
Jun 14 2032 | 2 years to revive unintentionally abandoned end. (for year 8) |
Jun 14 2033 | 12 years fee payment window open |
Dec 14 2033 | 6 months grace period start (w surcharge) |
Jun 14 2034 | patent expiry (for year 12) |
Jun 14 2036 | 2 years to revive unintentionally abandoned end. (for year 12) |